| // The contents of this file are in the public domain. See LICENSE_FOR_EXAMPLE_PROGRAMS.txt | |
| /* | |
| This is an example illustrating the use of the GUI API as well as some | |
| aspects of image manipulation from the dlib C++ Library. | |
| This is a pretty simple example. It takes a BMP file on the command line | |
| and opens it up, runs a simple edge detection algorithm on it, and | |
| displays the results on the screen. | |
| */ | |
| using namespace std; | |
| using namespace dlib; | |
| // ---------------------------------------------------------------------------- | |
| int main(int argc, char** argv) | |
| { | |
| try | |
| { | |
| // make sure the user entered an argument to this program | |
| if (argc != 2) | |
| { | |
| cout << "error, you have to enter a BMP file as an argument to this program" << endl; | |
| return 1; | |
| } | |
| // Here we declare an image object that can store rgb_pixels. Note that in | |
| // dlib there is no explicit image object, just a 2D array and | |
| // various pixel types. | |
| array2d<rgb_pixel> img; | |
| // Now load the image file into our image. If something is wrong then | |
| // load_image() will throw an exception. Also, if you linked with libpng | |
| // and libjpeg then load_image() can load PNG and JPEG files in addition | |
| // to BMP files. | |
| load_image(img, argv[1]); | |
| // Now let's use some image functions. First let's blur the image a little. | |
| array2d<unsigned char> blurred_img; | |
| gaussian_blur(img, blurred_img); | |
| // Now find the horizontal and vertical gradient images. | |
| array2d<short> horz_gradient, vert_gradient; | |
| array2d<unsigned char> edge_image; | |
| sobel_edge_detector(blurred_img, horz_gradient, vert_gradient); | |
| // now we do the non-maximum edge suppression step so that our edges are nice and thin | |
| suppress_non_maximum_edges(horz_gradient, vert_gradient, edge_image); | |
| // Now we would like to see what our images look like. So let's use a | |
| // window to display them on the screen. (Note that you can zoom into | |
| // the window by holding CTRL and scrolling the mouse wheel) | |
| image_window my_window(edge_image, "Normal Edge Image"); | |
| // We can also easily display the edge_image as a heatmap or using the jet color | |
| // scheme like so. | |
| image_window win_hot(heatmap(edge_image)); | |
| image_window win_jet(jet(edge_image)); | |
| // also make a window to display the original image | |
| image_window my_window2(img, "Original Image"); | |
| // Sometimes you want to get input from the user about which pixels are important | |
| // for some task. You can do this easily by trapping user clicks as shown below. | |
| // This loop executes every time the user double clicks on some image pixel and it | |
| // will terminate once the user closes the window. | |
| point p; | |
| while (my_window.get_next_double_click(p)) | |
| { | |
| cout << "User double clicked on pixel: " << p << endl; | |
| cout << "edge pixel value at this location is: " << (int)edge_image[p.y()][p.x()] << endl; | |
| } | |
| // wait until the user closes the windows before we let the program | |
| // terminate. | |
| win_hot.wait_until_closed(); | |
| my_window2.wait_until_closed(); | |
| // Finally, note that you can access the elements of an image using the normal [row][column] | |
| // operator like so: | |
| cout << horz_gradient[0][3] << endl; | |
| cout << "number of rows in image: " << horz_gradient.nr() << endl; | |
| cout << "number of columns in image: " << horz_gradient.nc() << endl; | |
| } | |
| catch (exception& e) | |
| { | |
| cout << "exception thrown: " << e.what() << endl; | |
| } | |
| } | |
| // ---------------------------------------------------------------------------- | |